FR2568574A1 - Ionically conductive polymer and solid electrolyte employing it - Google Patents

Abstract

The increase in the ionic conduction of polymeric solid electrolytes takes place through the use of a polyethylene glycol alkyl ether of following general formula: R denotes H or CH3 or an alkali metal, with x between 2 and 40 and y between 2 and 100.

Description

Ionic conductive polymer and solid electrolyte by application
The present invention relates to an ion conductive polymer and a solid electrolyte using it.

 Ionic conductive polymers are generally known, based on polyethers, having an ionic conductivity barely greater than 10 7 Q 1 cm 1 at room temperature. Under these temperature conditions, it is not possible to use these polymers to produce solid electrolytes with satisfactory results. Generators: lithium electrochemicals, comprising a solid electrolyte based on such polymers, can only operate from 400C or 500C and for relatively low current densities.

The present invention relates to an ionic conductive polymer having polyether functions, characterized in that it consists of a polyethylene glycol alkyl ether of general formula
CH3 - (CH2) - (O - CH2 - CH2) - O - R where x is between 2 and 40, where y is between 2 and 100, and where R denotes H or CH3 or an alkali metal.

 It is desirable that the total molecular weight of the polymer be greater than 300.

 Preferably its hydrophilic-lipophilic balance (H.L.B) is greater than 3.

 The present invention also relates to a solid electrolyte applying the preceding polymer.

 In addition to said polymer, said electrolyte comprises at least one ionizable salt of formula MX, M being chosen from Li +, Na +, K +, Ca2 +, Nu4 +, X being chosen from Cl04, CF3S03, SCN, BF4, I, Br, N3, BH4 , CF3CO3, B (C6H5) 4 the weight proportion of said salt in the mixture being at least 5%.

 It may also comprise a complexing polymer chosen from a polyethylene oxide, a propylene polyoxide, a random, alternating, block or graft copolymer of polyethers. This addition of complexing polymer is necessary when the polyethylene glycol alkyl ether does not exhibit satisfactory mechanical strength at the temperature of use.

 Mixing with another ionic conductor of polyether type can be envisaged without limitation of proportions.

 In all cases, the ratio of the total number of ether units to the number of cations present in the electrolyte is preferably between 5 and 8.

 The ionic conductivity of the polymers according to the invention is greater than 10-6J1-1 cm 1 at ordinary temperature.

 Solid electrolytes based on these polymers can be used in primary or secondary electrochemical generators, double electrochemical layer supercapacitors, electrochromic displays, sensors, and all applications of microionics using solid electrolytes.

 Other characteristics and advantages of the present invention will appear during the following description of three embodiments given by way of illustration but in no way limitative.

EXAMPLE 1
Dissolve in 30 cm3 of tetrahydrofuran THF at 400C: - 320 mg of polyoxyethylene stearyl ether of formula C18H37 (0CH2CH2) 200H - 80 mg of Lit104
After complete dissolution, the solvent is evaporated and the mass obtained is dried under primary vacuum for 15 hours at 1000C.

After shaping the electrolyte by pelleting in a metal matrix at room temperature, the continuous ionic conductivity measured at 250C on a symmetrical lithium / electrolyte / lithium element is 3.70 x 10 # 6JL # 1 cml.

EXAMPLE 2
An electrolyte containing - 320 mg of polyoxyethylene (M = 900,000) - 200 mg of polyoxyethylene lauryl ether of formula C12H25 (oCH2CH2) 23oH - 100 mg Licol04 is produced according to the procedure of Example 1
The shaping of the electrolyte is done by casting on a Teflon mold. One can thus obtain an electrolyte film whose ionic conductivity measured at 250C is 1 x 10-6 # -1 cm-1.

EXAMPLE 3
An electrolyte containing - 360 mg of polyoxyethylene (M = 900,000) - 300 mg of polyoxethylene stearyl ether - 72 mg of LiCl04 is produced according to the procedure of Example 1
The ionic conductivity # measured at 250C is 4.50 x 10 6 t 1 cl 1.

 Of course, the invention is not limited to the embodiments which have just been described. Without departing from the scope of the invention, any means can be replaced by equivalent means.

Claims (6)

1 / Ionic conductive polymer having polyether functions, characterized in that it consists of polyethylene glycol alkyl ether of general formula CH3 - (CH2) x - (O - CH2 - CH2) - O - R where x is between 2 and 40, where y is between 2 and 100, and where R denotes H, or CH3 or an alkali metal. 2 / an ion-conducting polymer according to claim 1, characterized in that its total molecular mass is greater than 300. 3 / Polymer according to one of claims 1 and 2, characterized in that its hydrophilic-lipophilic balance is greater than 3. 4 / solid electrolyte, characterized by the fact that it comprises the ionic conductive poly maer according to one of claims 1 to 3 and at least one ionizable salt of formula M X, M + being chosen from Li +, Na, K Ca2 +, NA; X being chosen from Cl04, CF3S03; SON, BF4, I, Br, N3, BH4, CF3CO #, B (C6H5> 4 the proportion by weight of said salt in the mixture being at least 5%.  5 / solid electrolyte according to claim 4, characterized in that it further comprises a complexing polymer chosen from a polyethylene oxide, a propylene polyoxide, a random, alternating, block or graft copolymer of polyethers. 6 / solid electrolyte according to one of claims 4 and 5, characterized in that the ratio of the total number of ether units to the number of cations present in the electrolyte is between 5 and 8.